Method and device for measuring distance

ABSTRACT

The invention relates to a frequency-shifted feedback radiation source, equipped with an element for increasing the beat intensity of the emission frequency component.

This invention concerns the general claimed device and thereby deals with the frequency shifted feedback emission sources and their use in measuring distance.

Techniques of measuring distances optically have been familiar for a long time. Besides echo sounding measurements, in which short light pulses are transmitted and the time elapsed until the backscattered or reflected pulse is measured, others familiar techniques involve interferometric processes.

An interferometric process entails splitting a light beam into a reference light beam and an object light beam. The object light beam is irradiated onto an object and reflected back from the object. The reference light beam and the object light beam are then superimposed on a light sensor and the distance to the object is derived from the superimposed signal. According to the configuration, this procedure produces very precise measurements; however, the depth measurement of extended objects at different locations creates difficulties.

Performing distance measurements with frequency deviation feedback lasers and frequency shifted feedback lasers (FSF laser) is also known. Examples of the FSF laser are to be found in the writings of F. V. Kowalski, P. D. Hale and S. J. Shattil.

“Broadband continuous-wave lasers,” Opt. Lett. 13, 622 (1988), and P. D. Hale and F. V. Kowalski “Output characteristics of a frequency shifted feedback laser: theory and experiment” IEE J. Quantum Electron. 26, 1845 (1990) as well as K. NAKAMURA, T. MIYAHARA, M. YOSHIDA, T. HARA and H. ITO “A new technique of optical ranging by a frequency-shifted feedback laser,” IEEE Photonics Technology Letters, Volume 10, 1998 Pages 1772 pp. An example of the application of such a laser for distance measurement is described in detail in the article “Obervation of a highly phase-correlated chirped frequency comb output from a frequency-shifted feedback laser” by K. NAKAMURA, T. MIYAHARA and H. ITO, Applied Physics Letters, Volume 72, No. 21, pages 2631 pp. and in the article “Spectral Characteristics of an All Solid-State Frequency-Shifted Feedback Laser” by K. NAKAMURA, F. ABE, K. KASAHARA, T. HARA, M. SATO and H. ITO in IEEE-JOURNAL OF QUANTUM ELECTRONICS, Volume 33, pages 103 pp. Also refer to I. C. M. Littler, S. Balle and K. Bergmann “The cw modeless laser: spectral control, performance data and build-up dynamics” Opt. Commun. 88, 514 (1992) and S. Balle, F. V. Kowalski and K. Bergmann “Frequency shifted feedback dye laser operating at small frequency shift” Opt. Commun. 102, 166 (1993) and G. Bonnet, S. Balle, Th. Kraft and K. Bergmann “Dynamics and self-modelocking of a Titanium-Sapphire laser with intracvacity[sic] frequency shift” Opt. Commun. 123, 790 (1996). The three latter documents expand on FSF lasers according to the current state of technology. These documents are also comprehensively categorized by reference in DE 100 45 535 for purposes of disclosure.

The principle of distance measurement with an FSF laser, which also contains an acousto-optical modulator in its resonator, in addition to an amplification medium, may be briefly presented as follows: amplification of light from the light waves entering into the amplification medium occurs for each frequency in which the amplification is greater than 1. For all other frequencies the light is diminished as usual. The optical resonator now has preferred frequencies, similar to a vibrating string, so-called resonator modes. Each resonator mode has a specific frequency, i.e. it corresponds to light of a precisely specified wavelength. Each resonator mode, in which the amplification of the amplifying medium is greater than 1, will now be emitted as a preference.

This is principally the behavior of a laser without an acousto-optical modulator. If the acousto-optical modulator now becomes excited, the material oscillations create a moving grid that varies in its density at various places; the light traveling around in the resonator is diffracted at this density grid, whereby an interaction of the light photons with the photons characterizing the density oscillations of the acouto-optical modulator occurs, which shifts the frequency of the diffracted light by the excitation frequency of the acousto-optical modulator. This leads to the laser modes shifting in time insignificantly in the frequency, changing the frequency of a mode in time; when there is more than one mode, this also applies to all modes that are oscillating in the resonator. This means, however, that according to the extent the amplification 1 of the amplification profile runs, the intensities of the individual oscillating modes are different and that the mode intensity changes with the frequency. It is makes sense that the frequencies change for all modes equally with time. In other words, light that is emitted at different times will possess different frequencies.

Light beams that are irradiated over optical paths of varying length now flow to a location similar to a detector, i.e. they were also emitted at different times from the laser, so there must be a frequency difference between the two. This frequency difference can be detected as a beat frequency on a photo-sensitive element. The length of distance traveled can be determined from the beat frequency.

The familiar measuring set-up is described in the documents referred to above.

In practice, it has been shown that the signals at the measuring receiver are strongly degraded by a high noise level. If the distance that is to be determined is fixed, a single sharp line without noise in the beat frequency would be observed. In reality, however, it turns out that instead that a very broad structure instead of a sharp line is received with FSF lasers, which severely impairs the quality of the received measurement.

It is desirable to change the known setups and processes in such a way that the applicability can be increased.

The task of this invention is to make something new available for commercial application.

Claims for the solution to this task are made in independent form. This invention proposes a frequency shifted feedback emission source that uses a means for increasing emission frequency component beat intensity.

Accordingly, it was not only recognized that the prevailing assumption in the interpretation of the state of technology that the beat portions coming from individual modes of the frequency shifted lasers would add up is not correct; rather, they interfere destructively. Surprisingly, the signal that can be achieved in the current state of technology with FSF lasers rests on the fact that noise in the operation of the known lasers, i.e. occurrence of fluctuation of intensity and/or phase, which prevents the occurrence of a—theoretically awaiting more exact analysis—completely destructive interference of the frequency components that are coherent to one another, as would otherwise occur. For measurements using FSF lasers, according to the current state of technology, conditional noise accordingly appears not to be a consequence of the noise of the laser; rather, it is the actual measurement signals themselves that are conditioned by the noise of the lasers, i.e. their inherent fluctuations.

Based on this knowledge it is now not only proposed that the emitter be equipped with means to increase the intensity of the beat vibration of frequency components of the emitted beam, but it is also specified how this knowledge can better be used to improve locally resolved object distance measurement.

In a preferred variation, the means for increasing emission frequency component beat intensity are configured as a means for increasing non-stochastic emission frequency component beat intensity, the means will therefore condition an intensity increase brought about by spontaneous emission, in particular in the amplification medium.

Typically an injection light source is used that injects light into the emitter, i.e. a seed emission field is arranged there. As an alternative, it would also be possible to interfere with complete destructive interference of frequency components via the measurement conditioned by spontaneous emission in the stationary operating condition by modulating the pump light somewhat, which is typically less preferred due to the level duration, etc. or by bringing about a somewhat fast loss mechanism in the amplification medium itself. The presence of an injection light source, however, is especially advantageous because it is an easy to build option through which a number of advantageous configurations can be realized.

A particularly advantageous variation for an injection light source is an injection laser. The emission of the laser can be guided into the resonator, in particular, in and/or to the amplification medium of the frequency shifted feedback emitter.

It is preferred when the injection light source emits light at a wavelength that is close to the wavelength at which the amplification of the amplification medium of the frequency shifted feedback emitter is at 1; it may optionally be irradiated close to the upper and/or lower threshold wavelength. The frequency of the injected light emission will typically be within the range in which the amplification G is greater than 1 and not outside of that range. For seed radiation injected very close to the threshold, and, particularly, modulation of the same, this threshold may temporarily be exceeded. It would always be preferable to select the irradiation frequency in such a way that amplification occurs no later than after a few resonator revolutions.

It is preferred when the injection light source emits narrowband irradiation whereby the narrowband radiation is incorporated into the amplification bandwidth of the amplification medium of the frequency shifted feedback emitter. In this instance, narrowband can refer to a bandwidth no greater than 5%, preferably not over 1% of the amplification bandwidth. In a particularly preferred variation, a single-mode injection laser with a precisely defined, modulating frequency and/or amplitude can be used for the injection.

The injection light irradiation preferably varies with regard to intensity and/or phase. This variation can occur due to a regular modulation, i.e. modulation of intensity and/or phase subject to preset principle moderation or limitations, which do not necessarily need to be uniform.

It is especially preferred when the modulation is not constant but when the intensity and/or the phase of the modulation of the injection light emission varies with time, which occurs best in a periodic manner. It is especially preferred when the frequency of the intensity modulation is changed within specified intervals because a linear variation of the modulation frequency of the injection light emission significantly simplifies an assessment of received beat vibration signals for measuring distance.

When a modulation of the emission emitting from the injection light source with respect to phase and/or intensity is performed, it is preferred when the frequency of this modulation lies close to the frequency occurring from the so-called chirp rate and the distance that is determined with the emission source immediately. The chirp rate is provided by the frequency of the acousto-optical or other modulator within the frequency shifted feedback emission source referring to the revolution period of the emission in the resonator of this source.

It may be mentioned that the emission source is typically a frequency shifted feedback laser. This may work in particular in infrared ranges that are safe to the eye. The wavelength ranges that are technologically well open and particularly cost-efficient for telecommunications devices may also be used for purposes of this invention, which opens the possibility of accessing cost-effective available elements for designing configurations and devices.

It can be seen that the described emission source used in the invention can be used in a configuration to measure distance. Beam expansion optics can be used, which expand the irradiation from the frequency shifted feedback emission source so wide that the surface to be investigated is illuminated broadly on and off and a means is then used to gain height profile information from the backscattering from the surface directly. Alternatively or additionally it is possible to irradiation partial ranges of the object and gain information about distances.

The invention will now be described in the following as examples using illustrations. These illustrations show:

FIG. 1 a schematic design of a frequency shifted feedback emission source that conforms to the in;

FIG. 2 the frequency variation of a single laser mode when using a linear chirp over time;

FIG. 3 the synchronous variation of all components (modes) of an emission light source with frequency shifted feedback conforming to the invention;

FIG. 4 the frequency spectrum of an FSF laser for the given amplification curve (top of image);

FIG. 5 a schematic design for a distance measurement with a configuration that conforms to the invention;

FIG. 6 a grayscale display of a beat frequency spectrum, as can be achieved from the current state of technology, with an artifact structures that are independent of position and a weak measurement signal that is recognizable as stripes running diagonally through the image;

FIG. 7 an example of a beat frequency signal dependent on a seed emission frequency modulation.

As shown in FIG. 1 a general frequency shifted feedback emission source 1 designated as 1 includes a means 2 for increasing emission frequency component beat intensity.

The frequency shifted feedback emission source 1 in this example is a ring laser with frequency shifted feedback. The ring resonator of the ring laser 1 is formed through two high reflecting mirrors 1 a, 1 b and an acousto-optical modulator 1 c to which a piezo element 1 c 1 as an actuator and input and outputs prisms 1 c 2, 1 c 3 are arranged and then configured in the resonator ring in such a way that the zeroed diffraction order, displayed as a beam 3 that can be coupled out while the first diffraction order guides the light circulating in the resonator. The acousto-optical modulator 1 c is selected in such a way that the diffractions efficients of more than 90% result for the first diffraction order frequency shifted in the familiar way through the acousto-optical modulation. The geometry is also selected in such a way that the prisms 1 c 2, 1 c 3 arranged on the acousto-optical modulator 1 c are compensated with regard to their dispersion and is still possible in a compact design.

A fiber medium 1 d is configured between both high-reflecting mirrors 1 a and 1 b to which a fiber launch and catcher optics 1 d 1 and 1 d 2 are arranged. Energy from a point laser designed here as a diode laser (not shown) is irradiated into the fiber so that it can be used as an amplification medium. The launch occurs on a fiber coupler 1 e. The displayed fiber is a traditional ytterbium fiber with a large useable amplification bandwidth of at least 70 nm, in this example, in the spectral range around 1.2 μm; such elements are easily available from the area of optical telecommunications, exactly like other, equally applicable configurations, for example, fiber lasers on the basis of YAG at 1.06 μm with a few m of bandwidth or erbium of 1.5 μm could be used.

The configuration of the FSF laser, as it has been described up to this point, is essentially traditional. Means for increasing emission frequency component beat intensity will be used. For that purpose there is a fiber coupler 2 a that is used to couple injection light into the fiber, indicated in 2 b, using a launch optic 2 c. The injection light 2 b comes from an injection laser (not shown) that with regard to its amplitude and the phase of the optical carrier can be modulated in a temporally variable manner. The injection or seed laser emits radiation whose wavelength lies up close to the lower position G=1 of the amplification profile of the FSF ring laser 1 or the fiber 1 d displayed for the up-chirp, compare FIG. 4, where in the upper portion of the image the amplification profile is illustrated as running lines, together with the amplification threshold 1, which is drawn horizontally and whereby the optical carrier frequency of the seed laser is entered as a vertical, hash line.

It can be mentioned at the same time that instead of, and/or besides, a launch via a fiber coupler 2 a, a launch of an injection light beam through one of the high-reflecting mirrors would also be possible, as indicated with mirror 1 a through beam 2 b 2, and/or a launch could occur into the acousto-optical modulator, as indicated by arrow 2 b 3. For the sake of completeness, it is also indicated here that the pump light that is different in this instance from the injection light, indicated with 1 e 1, can not only be launched via a fiber coupler into the amplifying fiber 1 d from the pump light beam 1 e 1, but, for example, a pump light launch is possible via the high-reflecting mirror as indicated by the beam 1 e 2 close to the mirror 1 b.

This configuration is operated as follows:

A pump light is irradiated on the fiber 1 d to bring about an inversion that makes laser operation possible. Then the piezo driver 1 c 1 of the acousto-optical modulator begins to oscillate so that the ring of the frequency shifted feedback laser is closed. Light, that is now emitted from the fiber can now run over the mirror 1 a, through the prism 1 c 2 and the acousto-optical modulator 1 c 1 and the prism 1 c 3. The major portion of this light will thereby irradiated into the fiber 1 d corresponding to the high diffraction efficiency of the acouto-optical modulator linked to the mirror 1 b 1.

When passing through the acousto-optical modulator 1 c, the frequency of the light changes simultaneously. The light that has run in the direction of the to the acousto-optical modulator with a preset frequency at the mirror 1 a, will therefore strike at the other high-reflecting mirror 1 b with a shifted frequency or wavelength. This light with shifted frequency is amplified in the fiber 1 d, runs again over the mirror 1 a under further frequency shifting through the acousto-optical modulator 1 c to the mirror 1 b, etc. This leads to the shifting of the frequency upon each pass. The speed used to change the frequency depends on the time it takes for the light to make a pass and how strong the frequency shift in the acousto-optical modulator is. The shift occurs for all components or modes that can be amplified in the resonator in the same way so that the frequency comb represented by the modes of the FSF laser are gradually shifted in a synchronous manner. There is a so-called “chirp.” This is displayed in FIG. 3, whereas FIG. 2 displays the variation of the frequency for a given linear chirp.

This light is now used to measure distances. This will only be discussed in principle first for a not yet locally resolved interferometer configuration, as displayed in FIG. 5, in which the invention light source 1, a beam segmenting element 4 in the catcher beam 3 of the light source 1, a reference path 6 to a reference surface 6′ and measurement path 7 to a measurement object 7′ are displayed, whereby the beams from the reference object 6′ and from the measurement object 7′ are guided to a detector 5.

The situation that arises in such a configuration for taking the seed source into operation on the detector, can be seen in image 6. A grayscale display of the beat frequency spectrum is displayed for a laser configuration as a function of the path difference ΔL of the arms 6 and 7 of the measurement configuration. In the grayscale display, the lines can be seen that are position-independent and do not vary with the path difference ΔL and thereby run horizontally in the image; the lines are conditioned by a standing wave portion in the acousto-optical modulator and repeat themselves after the resonator pass run time.

Further, it can be seen that the actual measurement signal has strong noise interference, which runs diagonally as a dark stripe through the image.

Now the injection light source is taken into operation and with a carrier frequency close to the lower range of the amplification curve, i.e. just still inside that range, in which the amplification is greater than 1. The optical carrier frequency this is drawn vertically is modulated, and amplitude modulated in this example, whereby the modulation itself is also not constant, but varies with a frequency that is nearly determined from the so-called chip rate, i.e. the frequency shift per resonator pass divided by the resonator pass time and is further determined by the light run time along the path difference ΔL between the measurement beam path and the reference beam path as in the design of FIG. 5. The modulation frequency of the injection light is therefore not held constant, but varies around this so-called signature value, i.e. around the value this results from the chirp rate and ΔL through the formula Δν=α×ΔL×c ⁻¹ whereby c is the light speed. The modulation frequency is changed around this signature frequency and is preferred in a linear saw tooth form. An intensity is yielded at the detector, as is displayed in FIG. 7. It turns out that a very significantly manifested, sharp intensity peak of the beat signal can be obtained, i.e. the signal is degraded very little from noise and in particular shows a minor degree of noise and thereby a more precise measurement than has been possible up to this point in the current state of technology. It is significant that the injection emission modulation and the beat frequency intensity are tightly linked to one another and a beat frequency intensity maximum is then achieved when the injection modulation frequency corresponds to the frequency expected for a given path difference taking the chirp rate into account.

Presently this is justified as follows: Through the injection of the irradiation of the injection laser at the edge of the amplification range, modes are shifted in the resonator in steps Δν_(AOM) over the entire amplification bandwidth so that the laser does not end up in a stationary, practically noise-free equilibrium at which it otherwise would sink. Accordingly, it seems that the traditional image of the coming into position of the beat spectrum is incorrect and actually in a noise-free instance the intensity of a beat would disappear.

In can now be determined that the structure width of the received signal structure is determined by the amplification bandwidth, i.e. a high bandwidth of the emission light source with the frequency shifted feedback, i.e. of the FSF laser, leads to a good spatial resolution. Because additionally the distance measurement precision is essentially determined by the chirp magnitude, it is desirable to select a large frequency shift through the acousto-optical modulator and a small laser resonator length of the FSF laser resonator.

It can be determined that during a distance measurement and, if necessary, during successive distance measurements at a specific time interval, a very high degree of precision can be achieved even during speed and/or acceleration measurements that essentially only depend on the driver frequency consistency of the acousto-optical modulator, as well as the laser resonator length stability during the measurement time. In addition, only magnitudes such as the precision of the beat frequency determination need to be taken into consideration. It is evident that systematic resolutions and precisions of 10⁻⁶-10⁻⁸ can be achieved. Through the significantly improved signal noise ratio it is also possible to perform measurements using very low power levels because only a high frequency portion in the detected signal must be detected as a beat and this portion consists of familiar or nearly familiar frequencies. 

1. Frequency shifted feedback emission source, characterized by the fact that a means is used to increase emission frequency component beat intensity.
 2. Frequency shifted feedback emission source according to claim 1, characterized by the fact that the means to increase emission frequency component beat intensity is configured as means for non-stochastic emission frequency component beat intensity increasing.
 3. Frequency shifted feedback emission source according to claim 2, characterized by the fact that the means to increase emission frequency component beat intensity includes an injection light source.
 4. Frequency shifted feedback emission source according to claim 3, characterized by the fact that the injection light source includes and injection laser.
 5. Frequency shifted feedback emission source according to claim 3, characterized by the fact that the injection light source is configured to inject irradiation into the resonator of the frequency shifted feedback emission source, specifically for irradiation into the amplification medium.
 6. Frequency shifted feedback emission source according to claim 3, characterized by the fact that the injection light source is configured for emission of irradiation of an irradiation frequency close the upper or lower amplification threshold (G-1).
 7. Frequency shifted feedback emission source according to claim 3, characterized by the fact that the injection light source for the irradiation of injection light is narrowband in reference to the amplification bandwidth of the frequency shifted feedback emission source, specifically a width below 5%, preferably below 1% of the bandwidth of the amplification of the frequency shifted feedback emission source.
 8. Frequency shifted feedback emission source according to claim 3, characterized by the fact that the injection light source is configured for irradiation of the appropriate intensity and/or phase of the optical carrier.
 9. Frequency shifted feedback emission source according to claim 8, characterized by the fact that the injection light source is configured for regular modulation of intensity and/or phase of the injection light.
 10. Frequency shifted feedback emission source according to claim 9, characterized by the fact that the injection light source is configured to perform a periodic modulation of intensity and/or phase that changes with time.
 11. Frequency shifted feedback emission source according to claim 9, characterized by the fact that the injection light source is configured so at least temporally one linear modulation frequency variation takes place.
 12. Frequency shifted feedback emission source according to claim 8, characterized by the fact that the injection light source is configured so that a modulation lies in the magnitude order and/or close to the distances determined using the emission source and the given chirp rate from the frequency shifted feedback emission source is obtained.
 13. Frequency shifted feedback emission source according to claim 1, characterized by the fact that the frequency shifted feedback emission light source is a laser.
 14. Frequency shifted feedback emission source according to claim 1, characterized by the fact that an optic fiber is used internally in the resonator.
 15. Distance measurement configuration with an emission light source according to claim
 1. 16. Distance measurement configuration according to claim 15, characterized by the fact that irradiation optics are used to broadly illuminate a surface to be investigated with light from the emission source and a means is used to obtain a beat spectrum containing height profile information.
 17. Distance measurement configuration according to claim 1, characterized by the fact that an optic is used to direct irradiation from the emission light source to a defined partial range of the object.
 18. Process for operating a frequency shifted feedback emission light source, characterized by the fact that the beat intensity of the frequency components of the emitted irradiation are increased beyond what is achieved in a stationary condition through spontaneous emission.
 19. Frequency shifted feedback emission source according to claim 4, characterized by the fact that the injection light source is configured to inject irradiation into the resonator of the frequency shifted feedback emission source, specifically for irradiation into the amplification medium.
 20. Frequency shifted feedback emission source according to claim 4, characterized by the fact that the injection light source is configured for emission of irradiation of an irradiation frequency close the upper or lower amplification threshold (G-1). 